View clinical trials related to Diabetic Foot Ulcer.
Filter by:The impacts from diabetes are both patient related and healthcare based. Offloading is recognised as the priority treatment for healing neuropathic and neuro-ischaemic plantar foot ulcers. The new PulseFlow DF boot is a device which claims to off load but has little or no evidence on diabetic foot ulcer (DFU) subjects. Thus the primary aim of this study is to observe forefoot plantar pressures in a cross sectional purposively selected sample compared to usual standard of care.
A double blind, randomized controlled clinical trial comparing wound closure rates of diabetic foot ulcers (DFUs) in subjects receiving active RIC treatment plus standard of care compared to those receiving sham treatment plus standard of care.
This pilot study wants to determine to which extent SPCCT allows obtaining images with improved quality and diagnostic confidence when compared to standard Dual Energy CT (DECT), both with and without contrast agent injection. Depending on the anatomical structures/organs to be visualized during CT examinations, different scanning protocols are performed with quite variable ionizing radiation doses. Therefore, in order to obtain the most extensive and representative results of the improvement in image quality between SPCCT and DECT that will be performed CT imaging on several body regions and structures, including diabetic foot, diabetic calcium coronary scoring, adrenal glands, coronary arteries, lung parenchyma, kidney stones, inner ear, brain and joints, earl/temporal bone, colorectal carcinosis.
With the available molecular and cellular evidence of impaired wound healing due to hyperglycemia, investigators postulate hypothesis asking whether intensive glycemic control could improve diabetic foot ulcer healing rates. A study showed improvement in phagocytic activity of macrophages after 5 days of intensive glycemic improvement in 21 patients of diabetes. Another retrospective cohort study studied the effect on HbA1c as predictor of healing rate in DFU. Latter found significant association of HbA1c with wound area healing rate. However a recent systematic review failed to find any randomized control trial comparing the effect of intensive versus conventional glycemic control for treating DFU. Hence, investigators want to explore the hypothesis by conducting a randomized control trial with the primary aim of wound healing in patients of diabetic foot ulcer in response to intensive glycemic control in comparison to conventional glycemic management.
This study is designed to evaluate if how people are told to return to walking after a skin injury affects whether or not they develop new (recurrence) skin breakdown on their feet. The people in this study will have diabetes and have a recently closed foot ulcer. About half will be specifically told how to return to walking and the other half will be told to return to walking slowly. How people naturally return to walking will also be established.
Diabetic and venous ulcers affect many people, and severe cases can end up in amputation and even death because of infection. In 2011, the total cost for care of diabetic foot ulcers alone, to the Canadian health care system, was $547 million. Standard clinical care for these types of wounds has improved but there is still a great need for new wound care treatments to help speed up wound healing and reduce pain. One such treatment is high intensity LED light therapy. There is a long history of light therapy showing faster wound healing, reduced pain and reduced swelling. The research we propose here is to study a new high intensity LED light made by Kerber Applied Research Inc., to see if it reduces pain and speeds up healing lower leg ulcers. This research is a partnership between Kerber Applied Research Inc and the Lethbridge Lower Limb Wound Clinic, an Alberta Health Services program in Lethbridge, Alberta.
The key purpose of this study is to determine and understand the safety and effectiveness of blue light phototherapy in the treatment and healing of infected diabetic wounds, as well as determining if this treatment is capable of reducing the bacterial population number within infected wounds. The investigators' lab recently discovered that a specific survival protein called catalase can be destroyed through blue light exposure. Given that a majority of bacteria species contains catalase, it is hypothesized that the destruction of this protein can improve the effectiveness of antimicrobial wound dressings commonly used to treat infected diabetic wounds, therefore further reducing the amount of bacteria within the wound and increasing the rate of healing. By reducing the overall bacterial population within these diabetic infected wounds, the ability for these diabetic wounds to heal will be enhanced, allowing for greater reductions in wound size over the course of the treatment. In this study, 40 subjects will be enrolled and randomly assigning subjects to either a control group or a phototherapy receiving experimental group. While control subjects will receive standard weekly debridement treatment procedures for infected diabetic ulcers, experimental subjects will receive standard weekly debridement treatment alongside 2 sessions of phototherapy every week over the course of 12 weeks. Bacterial swab samples will be taken alongside the excised debrided infect tissue for the purpose of bacterial population analysis. For each patient, the changes in total bacterial population, wound size, and subject satisfaction will be recorded and analyzed to determine the effectiveness of pulsed light phototherapy.
This is a two-part phase 1/2A study performed in diabetic foot ulcer (DFU) patients with chronic non-healing wounds to investigate the safety and efficacy of AUP1602-C.
This study seeks to establish the effect of adding exercise to off-loading interventions on the healing time for people with diabetes mellitus and a foot ulcer. Hypothesis: Consistent with the literature, results are expected to resemble the accelerated healing seen when older adults exercised in the presence of wounds.
Objectives: Diabetes has a prevalence of 11.6% in China with diabetic foot ulcerations affecting over 30 million Chinese. 85% of these patients require amputation and 5-year mortality for diabetics is 70% when associated foot ulcers. Clinical trials have shown that standing on whole-body vibration platforms, specifically low-magnitude high-frequency vibration (LMHFV); promotes angiogenesis, enhances muscle bulk and accelerates epithelization. Investigation on diabetic rats with foot wounds found accelerated wound healing, increased perfusion and upregulation of factors such as VEGF, PECAM-1 and PCNA. Hypothesis: The investigators postulate LMHFV will enhance diabetic foot ulcer healing. Design and Subjects: Prospective, single-centre, randomised control trial to treat 106 subjects with diabetic foot ulcers. Interventions: The intervention group will stand on LMHFV whole-body vibration platforms for 20min on alternate days for 20 weeks, together with conventional dressing by a trained wound-care nurse as in the control group. Main Outcome Measures: Ulcer size will be measured at multiple time points, the incidence of amputations/infections will be recorded, perfusion via ankle-brachial pressure index will be calculated and foot function via the foot and ankle outcome score will be analysed. Data analysis: Repeated measure of ANOVA to analyze time-point differences and student's t-test for same time-point comparison. Expected Results: This is the first clinical trial to investigate the effect of whole-body vibration on diabetic foot ulcers. It will show the investigators if the results from animal studies will translate into clinically significant results. If positive effects are established, whole-body vibration can be a valuable treatment regime to tackle diabetic foot ulcers.